Propulsion /

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Kerwin, Justin E. (Justin Elliot)
Otros Autores: Hadler, Jacques B., Paulling, J. Randolph
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Jersey City, N.J. : Society of Naval Architects and Marine Engineers, 2010.
Colección:Principles of naval architecture series.
Temas:
Ship propulsion.
Navires > Propulsion.
Military & Naval Science.
Law, Politics & Government.
Naval Architecture.
Acceso en línea:Texto completo

MARC

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049 |a UAMI 
100 1 |a Kerwin, Justin E.  |q (Justin Elliot) 
245 1 0 |a Propulsion /  |c Justin E. Kerwin and Jacques B. Hadler. 
264 1 |a Jersey City, N.J. :  |b Society of Naval Architects and Marine Engineers,  |c 2010. 
300 |a 1 online resource (xxii, 183 pages) :  |b illustrations (some color). 
336 |a text  |b txt  |2 rdacontent 
337 |a computer  |b c  |2 rdamedia 
338 |a online resource  |b cr  |2 rdacarrier 
490 1 |a The principles of naval architecture series 
504 |a Includes bibliographical references and index. 
505 0 0 |g 1. Powering of Ships.  |t 1.1 Historical Discussion --  |t 1.2 Types of Ship Machinery --  |t 1.3 Definition of Power --  |t 1.4 Propulsive Efficiency 
505 8 0 |g 2. Two-Dimensional Hydrofoils.  |t 2.1 Introduction --  |t 2.2 Foil Geometry --  |t 2.3 Conformal Mapping --  |t 2.4 Linearized Theory for a Two-Dimensional Foil Section --  |t 2.5 Glauter's Solution for a Two-Dimensional Foil --  |t 2.6 The Design of Mean Lines: The NACA a-Series --  |t 2.7 Linearized Pressure Coefficient --  |t 2.8 Comparison of Pressure Distributions --  |t 2.9 Solution of the Linearized Thickness Problem --  |t 2.10 Superposition of Camber, Angle of Attack, and Thickness --  |t 2.11 Correcting Linear Theory near the Leading Edge --  |t 2.12 Two-Dimensional Vortex Lattice Theory --  |t 2.13 Two-Dimensional Panel Methods --  |t 2.14 The Cavitation Bucket Diagram --  |t 2.15 Viscous Effects: Two-Dimensional Foil Sections 
505 8 0 |g 3. Three-Dimensional Hydrofoil Theory.  |t 3.1 Introductory Concepts --  |t 3.2 The Strength of the Free Vortex Sheet in the Wake --  |t 3.3 The Velocity Induced by a Three-Dimensional Vortex Line --  |t 3.4 Velocity Induced by a Straight Vortex Segment --  |t 3.5 Linearized Lifting-Surface Theory for a Planar Foil --  |t 3.6 Lift and Drag --  |t 3.7 Lifting Line Theory --  |t 3.8 Lifting Surface Results 
505 8 0 |g 4. Hydrodynamic Theory of Propulsors.  |t 4.1 Inflow --  |t 4.2 Notation --  |t 4.3 Actuator Disk --  |t 4.4 Axisymmetric Euler Solver Simulation of an Actuator Disk --  |t 4.5 The Ducted Actuator Disk --  |t 4.6 Axisymmetric Euler Solver Simulation of a Ducted Actuator Disk --  |t 4.7 Propeller Lifting Line Theory --  |t 4.8 Optimum Circulation Distributions --  |t 4.9 Lifting Line Theory for Arbitrary Circulation Distributions --  |t 4.10 Propeller Vortex Lattice Lifting Line Theory --  |t 4.11 Propeller Lifting-Surface Theory and Computational Methods 
505 8 0 |g 5. Unsteady Propeller Forces.  |t 5.1 Types of Unsteady Forces --  |t 5.2 Basic Equations for Linearized Two-Dimensional Unsteady Foil Theory --  |t 5.3 Analytical Solutions for Two-Dimensional Unsteady Flows --  |t 5.4 Numerical Time Domain Solution --  |t 5.5 Wake Harmonics and Unsteady Propeller Forces --  |t 5.6 Transverse Alternating Forces --  |t 5.7 Unsteady Three-Dimensional Computational Methods for Propellers --  |t 5.8 Unsteady Propeller Force Example 
505 8 0 |g 6. Theory of Cavitation.  |t 6.1 Introduction --  |t 6.2 Noncavitating Flow - Cavitation Inception --  |t 6.3 Cavity Flows - Formulation of the Problem --  |t 6.4 Cavitating Hydrofoils - Linearized Formulation --  |t 6.5 Numerical Methods --  |t 6.6 Leading Edge Correction --  |t 6.7 Panel Methods for Two-Dimensional and Three-Dimensional Cavity Flows --  |t 6.8 Cavitating Propeller --  |t 6.9 Comparisons with Experiments --  |t 6.10 Effects of Viscosity on Cavitation --  |t 6.11 Design in the Presence of Cavitation 
505 8 0 |g 7. Scaling Laws and Model Tests.  |t 7.1 Introduction --  |t 7.2 Law of Similitude for Propellers --  |t 7.3 Open-Water Tests --  |t 7.4 Model Self-Propulsion Tests --  |t 7.5 Wake Survey --  |t 7.6 Propeller Cavitation Tests 
505 8 0 |g 8. Propeller Design.  |t 8.1 Introduction --  |t 8.2 The Design and Analysis Loop --  |t 8.3 Definition of the Problem --  |t 8.4 Preliminary Design --  |t 8.5 Design Point --  |t 8.6 Analysis and Optimization of the Design 
505 8 0 |g 9. Waterjet Propulsion.  |t 9.1 Hydrodynamic Issues --  |t 9.2 Inlet Analysis --  |t 9.3 Pump Design and Analysis --  |t 9.4 Tip Leakage Flow 
505 8 0 |g 10. Other Propulsion Devices.  |t 10.1 Introduction --  |t 10.2 Tunnel Sterns --  |t 10.3 Vertical-Axis Propellers --  |t 10.4 Overlapping Propellers --  |t 10.5 Supercavitating Propellers --  |t 10.6 Surface Piercing Propellers --  |t 10.7 Controllable-Pitch Propellers 
505 8 0 |g 11. Propeller Strength.  |t 11.1 Introduction --  |t 11.2 Stresses Based on Modified Cantilever Beam Analysis --  |t 11.3 Bending Moments due to Hydrodynamic Loading --  |t 11.4 Centrifugal Force --  |t 11.5 Strength Analysis --  |t 11.6 Stresses Based on Finite Element Analysis --  |t 11.7 Minimum Blade Thickness Based on Classification Society Rules --  |t 11.8 Fatigue Analysis --  |t 11.9 Materials 
505 8 0 |g 12. Ship Standardization Trials.  |t 12.1 Purpose of Trials --  |t 12.2 Preparation for Trials --  |t 12.3 General Plan of Trials --  |t 12.4 Measurement of Speed --  |t 12.5 Analysis of Speed Trials --  |t 12.6 Derivation of Model-Ship Correlation Allowance. 
588 0 |a Print version record. 
546 |a English. 
590 |a Knovel  |b ACADEMIC - Mechanics & Mechanical Engineering 
590 |a Knovel  |b ACADEMIC - Marine Engineering & Naval Architecture 
650 0 |a Ship propulsion. 
650 6 |a Navires  |x Propulsion. 
650 7 |a Ship propulsion.  |2 fast  |0 (OCoLC)fst01116190 
650 7 |a Military & Naval Science.  |2 hilcc 
650 7 |a Law, Politics & Government.  |2 hilcc 
650 7 |a Naval Architecture.  |2 hilcc 
700 1 |a Hadler, Jacques B. 
700 1 |a Paulling, J. Randolph. 
776 0 8 |i Print version:  |a Kerwin, Justin E. (Justin Elliot).  |t Propulsion.  |d Jersey City, N.J. : Society of Naval Architects and Marine Engineers, 2010  |z 9780939773831  |w (DLC) 2010040103  |w (OCoLC)667213082 
830 0 |a Principles of naval architecture series. 
856 4 0 |u https://appknovel.uam.elogim.com/kn/resources/kpPNASP004/toc  |z Texto completo 
994 |a 92  |b IZTAP 

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